SU930140A1 - Device for measuring pulse train instantaneous frequency - Google Patents

Description

(54) DEVICE FOR MEASURING THE INSTANT FREQUENCY OF SUSHULS FOLLOWING

one

This invention relates to electrical measurements and is intended to measure the instantaneous frequency of low speed processes.

A device of a similar purpose is known comprising a time-to-voltage converter, a hyperbolic function generator and a start-and-stop control circuit 1.

A disadvantage of this device is the significant frequency measurement error due to the insufficiently high accuracy of reproduction of the hyperbolic function.

The closest in technical essence to the invention is a device for measuring low frequency, which contains a generator linearly; measuring voltage, two exponential converters, a comparator, a voltage divider, a reference voltage source, an instantaneous value voltmeter and a control unit.

consisting of a pulse former 2.

A disadvantage of the known device is the low accuracy of the frequency measurement due to the influence of the previous measurement cycle on the results of the subsequent one, which is the greater, the greater the difference in the duration of the cycles.

The methodical error of measurement of -10 is due to the start of the generator of a linearly varying voltage with a delay of the discharge time of the exponential converters.

Thus, when the input pulse frequency is changed, a large dynamic measurement error is observed.

The purpose of the invention is to improve the accuracy of frequency measurement.

20

Claims (2)

This goal is achieved by the fact that in a device containing a linearly varying voltage generator connected in series, a first exponential converter and a comparator connected to its second input through a voltage divider with a source of reference voltage, the second exponential converter, volt-meter instantaneous control unit, the input pulse source is connected to the second input of the first exponential transducer via the control unit and through the second exponential transducer the actor is connected to the analog instantaneous voltmeter input, the control input of which is connected to the comparator output, and the second input of the second dedicated converter is connected to the output of the voltage source, the comparator output is connected to the second input of the control unit, the second output of which is connected linearly to the generator input voltage changing. FIG. 1 shows a block diagram of the proposed device ;, FIG. 2 - its time diagrams; in fig. 3 - structure of the control unit; in fig. 4 - structure of the exponential converter. The device contains a linearly varying voltage generator 1, a first exponential converter 2, a comparator 3, a voltage divider 4, a reference voltage source 5, a second exponential converter 6, a voltmeter 7 of instantaneous value, a control unit 8 containing a single voltage 9, a trigger 10 Exponential transducers contain an emitter follower 11, a key 12, an exponential generator 13. The device operates as follows. A regular impulse (T;) of the measured frequency (Fig. 1) is supplied to the input of control unit 8 (Fig. 3). The impulse from the one-vibrator 9 output (from the output of block 8) is reset by the generator 1 of the linearly varying voltage (Fig. 2, the time t) and energizes the trigger 10, the output of which controls the exponential transform 2. During the operation of the control pulse received at the second input of Converter 2 from the first output of control unit 8 (from the output of trigger 10), the electronic key 12 is closed Simultaneously control pulse from the first output of the unit. The control 8 is fed to the input of the second exponential converter 6 and closes its key for the duration of its operation.The output voltage generated by the generator 1 of the linearly varying voltage after resetting from time t and repeated by the emitter follower 11 included in the first exponential converter 2 does not pass to the input of the exponential generator 13 of the converter 2 (Fig. 4). The generators of the first and second exponential transducers that are disconnected for the duration of the control pulse from charge voltage ovateley begin to form at its outputs exponentially varying voltage ekspb .n, respectively (FIG. 2). For the generator of the first exponential converter 2, the initial voltage at time t is equal to the output voltage of generator 1 of a linearly varying voltage supplied through the emitter follower 11 and the electronic key 12, i.e., t.i. (G.A.N. / 1a, for the exponential generator of the second exponential converter 6, the initial voltage at time t is equal to the constant voltage of the source 5 of the reference voltage, received through the open electronic key exp °, Then the process of forming exponentially varying occurs voltages and (spssb moment of equality I „„ on exGG KG where Kl is the voltage division factor of the divider 4; UQ is the voltage at the output of the voltage divider 4. The instantaneous value of the EXPB voltage is proportional to ent. moment .2 is fixed by the KOMnajiaTopOM × containing-gpcrm, for example, a comparison device, a differentiating circuit and a diode. When the condition U c is fulfilled, the output of the comparison device from the moment t2 to the moment tj appears on the differentiating The pulse generated by the differentiating circuit at time t on the falling edge of the pulse from the output of the comparison device has the polarity opposite to the pulse generated by the differential circuit at time tn and does not pass through the diode. The output pulse of the comparator 3 starts a voltmeter 7 of instantaneous values, which measures the voltage at time t2, Ij and the second input of control unit 8, flips trigger 10 of this block to its initial state (Fig. 2, tlgbtxe - P this control pulse The first output of the control unit 8 disappears, the keys 12 of the exponential transducers are closed, as a result of which the capacitor of the exponential generator of the transducer 6 is charged before the voltage of the source 5 of the reference voltage and the exponential generator The ora of the converter 2 is rapidly charged to the output, passed through the emitter follower 1I, the voltage of the generator 1 linearly changes the state voltage, and further repeats this voltage until the next measured frequency pulse arrives (Fig. 2, Uftj, x2). The proposed device for measuring the instantaneous pulse frequency differs from the known one with higher measurement accuracy and faster response. In the proposed device, the frequency measurement accuracy is higher due to the exception of systematic error and its measurement and reduce nonlinearity Niemi converting hour Toty sequencers voltage pulses. This is realized as a result of using for measuring the frequency of the actual time pulses between the NIS, EXCLUDING from it the time At forming an exponential change in kmcx of voltages by eliminating the generator starting voltage of the linearly varying voltage at time t and performing its start in the proposed device immediately after resetting at t, in contrast to the known device, where the generator is started at time t. Claims. A device for measuring the instantaneous pulse frequency, containing a linearly varying voltage generator, a first exponential converter and a comparator connected to its second input through a voltage divider with a voltage source, a second potential converter, a voltmeter of instantaneous values and a control unit the source of input pulses through the control unit is connected to the second input of the first exponential converter and through the second screen Potential converter — with an analog instantaneous value voltmeter input, whose control input is connected to the comparator output, and the second input of the second exponential converter is connected to the output of the reference voltage source, characterized in that, in order to improve the frequency measurement accuracy, the comparator output is connected to the second input of the control unit, the second output of which is connected to the generator input of the linearly varying voltage. Sources of information taken into account in the examination 1. Ut Mouse R. I. Radio engineering equipment for the study of physiological processes. M., Energie, 1969, p. 275-297. 2. USSR author's certificate number 619869, cl. G 01 R 23/00, 1978. Faye, 5 Fne.